Elucidating Pathfinding Elements from the Kubi Gold Mine in Ghana

Nzulu, Gabriel; Bakhit, Babak; Högberg, Hans; Hultman, Lars; Magnuson, Martin

doi:10.3390/min11090912

Cited by 7 publications

(5 citation statements)

References 79 publications

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“…These minerals consist of elemental components that form part of the mineral complexes and are believed to bond metallically, covalently, or form an alloy with gold. The chemical bonding and valence states of gold in the host minerals provide insights into the nature of gold mineralization and the mechanisms involved in the formation of gold deposits [30]. The ndings suggest that the oxidation state of Au is either Au 0 , Au 1+ , or Au 3+ depending on the speci c gold deposit and mineral composition.…”

Section: Discussionmentioning

confidence: 99%

“…On the other hand, the Au + 3 auric ion type bonds covalently and ionically, and as such, gold (III) ions form stable complexes with C, N, P, S, and O-donor ligands [30,31]. The average Au-S bond in pyrite (FeS 2 ) is 2.18-2.40 Å in agreement with literature [7], and the average Au-O bond in quartz (SiO 2 ) is 1.67-1.70 Å in agreement with the literature value of 1.67 Å [31] as listed in Table II.…”

Section: Discussionmentioning

confidence: 99%

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Chemical bonding and valence states in Au-associated host minerals

Nzulu,

Magnusson

2023

Preprint

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Natural minerals play a vital role and exhibit unique electronic and structural properties that can be attributed to the presence of gold. Therefore, research on the chemical bonding of these materials is essential for contributing to better exploration, separation, and recovery techniques. The study of minerals from mining areas and their differences in correlation to Au contributes to an understanding of the chemical forms of invisible gold in rocks as well as their association with other mineral deposits. Here, we investigate the structural chemistry of gold (Au) and pathfinder elements in soil sediments (Au concentrates) containing host minerals of pyrite (FeS2), magnetite (Fe3O4), and quartz (SiO2) identified by X-ray diffraction (XRD). The samples were collected at an alluvial small-scale mining site and investigated by X-ray absorption near edge structure (XANES) and extended X-ray absorption fine structure (EXAFS) at the Au 2p3/2 and Ag 1s absorption edges. XANES shows that the average valence states of Au have different weights of Au0, Au1+ and Au3+ depending on the composition of the host minerals at the mineral deposit. EXAFS shows that the interatomic Au-Au distances increase to 2.99–3.03 Å compared to 2.85 Å for Au metal, while the Ag-Ag distances increase to 2.93–2.97 Å compared to Ag metal of 2.86 Å. As shown in this work, XANES and EXAFS reveal the structural composition and chemical bonding of Au and Ag in host minerals that play an important role in the formation and stability of Au-associated mineral deposits. The results also reveal the alloying of Au with Ag and its association with S and O ligands in the host minerals as indistinguishable in X-ray diffraction. The knowledge will aid in mineral exploration and extraction based on geochemical data of the constituent minerals in potential geological zones.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Chemical bonding and valence states in Au-associated host minerals

Nzulu,

Magnusson

2023

Preprint

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“…The hybridization between Fe 3d and S 3p states, creates a charge transfer excitation from the completely lled Fe 3d-t 2g orbitals to the empty Fe 3d-e g antibonding states. Therefore, a shift in the binding energy (E b ) along the e g states of empty orbitals will covalently bond to other ligands due to σ interactions [30][31][32]. Thus, by understanding the conductivity of surface and bulk conditions from the optical and electrical characterization of FeS 2 , it should be possible to improve the electrical properties for PV applications.…”

Section: Discussionmentioning

confidence: 99%

Optical and electronic properties of pyrite

Nzulu,

Magnusson,

Mgnusson

2023

Preprint

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The optical and electronic properties of pyrite (FeS2) mineral have been investigated by ex-situ spectroscopic ellipsometry measurements made on pristine (bulk) FeS2. This method offers an alternative to petrographic microscopes used in many laboratories, as well as, in education and research institutions to study optical properties of rocks and minerals. The ability of spectroscopic ellipsometry to determine the dielectric function {ε (E) = ε1 (E) + iε2 (E)} of the material from its structural morphology, band gap, and electrical conductivity within the infrared spectral range (0.73–5.9 eV) is an added advantage over the optical microscopy that require ample time for thin section sample preparation to enable an optical light beam to be transmitted or reflected. As shown in this work, petrographic analyses of rocks and minerals using spectroscopic ellipsometry is a useful technique for optical studies of rocks and minerals with an added advantage over petrographic microscopy (optical microscopy).

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“…From geological, geochemical, and mineralogical perspectives, it is essential to study the chemical bonding, flow mechanism, phase transformation, and transport properties of minerals to understand the efficiency of heat transfer and thermal structure of the earth's mantle as well as the dynamics and evolution of Earth and other terrestrial planets. To date, there have not been such studies on the Kubi concession, and this research aims to increase the knowledge of the rheological properties (material deformation), thermo-chemical structure, the kinetics of phase transformation, and thermal conductivity of minerals in this study area [16].…”

Section: Acknowledgementmentioning

confidence: 99%

Characterization of Pathfinders and Indicators of Gold

Nzulu

2023

Linköping Studies in Science and Technology. Dissertations

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Research on natural minerals and their chemical bonding to economically critical raw materials is a viable industrially relevant research area due to its increasing demand. Meeting demands requires fast, robust, and efficient techniques to explore new ore deposits and continuous operation of active mines as well as recycling. One of the most critical metals is gold which occurs in three main types of ore deposits: i) hydrothermal quartz veins and related deposits in metamorphic and igneous rocks; ii) volcanic-exhalative sulfide deposits, and iii) consolidated to unconsolidated placer deposits. Gold is commonly found as disseminated grains in quartz veins in pyrite and other sulfides or as rounded grains, flakes or nuggets in deposits in riverbanks, in contact with metamorphic or hypothermal deposits (e.g., skarns) or epithermal deposits such as volcanic fumaroles. Pathfinder elements and indicator minerals provide means to explore large areas for their potential mineral commodities such as gold, diamond, base metals, platinum group of elements, and rare earth elements by narrowing the search area to reduce exploration costs. The recent technological advancement in obtaining rapid geochemical results using field portable analytical devices as alternatives to the old approach where collected field samples are carried to the laboratory calls for further investigation to explore other techniques in mineral and metal exploration.In this Thesis, I investigate the properties of artisanal small-scale gold mining concentrate, outcrop, bulk Au, and drill hole samples from the Kubi Gold Project of the Asante Gold Corporation near Dunkwa-on-Offin in the Central Region of Ghana with a materials science perspective. X-ray diffraction (XRD) is used to identify SiO2 (quartz), Fe3O4 (magnetite), garnet, pyrite (FeS2), periclase (MgO), arsenopyrites, pyrrhotite, biotite, titanium oxide, and Fe2O3 (hematite) as the main indicator minerals in the mining site with less significant contributions from chalcopyrite, iridosmine, scheelite, tetradymite, gypsum, and a few other sulfates. X-ray photoelectron spectroscopy (XPS) and energy dispersive X-ray spectroscopy (EDX) indicate that Fe,

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Elucidating Pathfinding Elements from the Kubi Gold Mine in Ghana

Cited by 7 publications

References 79 publications

Chemical bonding and valence states in Au-associated host minerals

Chemical bonding and valence states in Au-associated host minerals

Optical and electronic properties of pyrite

Characterization of Pathfinders and Indicators of Gold

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